Derivation of F=FeFp as the continuum limit of crystalline slip

Reina, Celia; Schlömerkemper, Anja; Conti, Sergio

doi:10.1016/j.jmps.2015.12.022

Cited by 31 publications

(26 citation statements)

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“…A substantial body of literature has emerged in materials science, engineering, and mathematics, see for instance [27,36] and the references therein, or more specifically, [23,29,40,44] for heterogeneous plastic materials, and [2,33,35] for fiber-reinforced materials, and [6,10] for high-contrast composites, to mention just a few references.…”

Section: Introductionmentioning

confidence: 99%

Homogenization of layered materials with rigid components in single-slip finite crystal plasticity

Christowiak

Kreisbeck

2017

Calc. Var.

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We determine the effective behavior of a class of composites in finite-strain crystal plasticity, based on a variational model for materials made of fine parallel layers of two types. While one component is completely rigid in the sense that it admits only local rotations, the other one is softer featuring a single active slip system with linear self-hardening. As a main result, we obtain explicit homogenization formulas by means of -convergence. Due to the anisotropic nature of the problem, the findings depend critically on the orientation of the slip direction relative to the layers, leading to three qualitatively different regimes that involve macroscopic shearing and blocking effects. The technical difficulties in the proofs are rooted in the intrinsic rigidity of the model, which translates into a non-standard variational problem constraint by non-convex partial differential inclusions. The proof of the lower bound requires a careful analysis of the admissible microstructures and a new asymptotic rigidity result, whereas the construction of recovery sequences relies on nested laminates. Mathematics Subject Classification 49J45 (primary) · 74Q05, 74C15

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Section: Introductionmentioning

confidence: 99%

Homogenization of layered materials with rigid components in single-slip finite crystal plasticity

Christowiak

Kreisbeck

2017

Calc. Var.

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“…The idea of approximating continuous maps by piecewise smooth maps appears also in the theory of structured deformations, proposed in [17] to study plasticity models (without a focus on dislocations) and analysed in [9,10], see also [18] for an overview and [37,38] for a related approach.…”

Section: Variational Models Of Dislocations and Plasticity In Crystalsmentioning

confidence: 99%

Homogenization of vector-valued partition problems and dislocation cell structures in the plane

Conti

Garroni

Müller

2016

Boll Unione Mat Ital

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We consider target-space homogenization for energies defined on partitions parametrized\ud by a discrete lattice B ⊂ RN. For a smallσ > 0, the variable is a piecewise constant\ud function taking values in σB, and the energy depends on the jumps and their orientation. In\ud the limit as σ → 0 we obtain a homogenized functional defined on functions of bounded\ud variation. This result is relevant in the study of dislocation structures in plastically deformed\ud crystals. We review recent literature on the topic and propose our limiting effective energy\ud as a continuum model for strain-gradient plasticity

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“…G.I. Taylor [1] realized that plastic deformation could be explained in terms of the theory of dislocations, even since this view has become a consensus that mechanism of plastic deformation is the result of dislocation accumulation [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][22][23][24]. Accordingly, some plastic dislocation density tensors have been proposed [2][3][4][5][6][7][8].…”

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confidence: 99%

“…Reina et al [11][12][13][14] did a comprehensive and in depth studies on the Ortiz's definition T Ortiz = −F p × ∇. Berdichevsky [8] introduced a measure of the resultant closure failure leading to the dislocation density tensor T Berdichevsky = −F p−1 · (F p × ∇).…”

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confidence: 99%